Diffraction grating element, production method of diffraction grating element, and method of designing diffraction grating element

ABSTRACT

In a diffraction grating element  10 , between a first medium  11  and a fourth medium  14 , a second medium  12  and a third medium  13  are disposed alternately to form a diffraction grating. The light, which enters the diffraction grating from the first medium  11 , is diffracted at the diffraction grating portion and output to a fourth medium  14 . Or, the light, which enters the diffraction grating from the fourth medium  14 , is diffracted at the diffraction grating portion and output to the first medium  11 . The index of refraction n 1 –n 4  of each medium satisfies a relational expression of “n 3 &lt;n 1 &lt;n 2 , n 3 ≦n 4 ≦n 2 ” or “n 3 ≦n 1 ≦n 2 , n 3 &lt;n 4 &lt;n 2 ”.

RELATED APPLICATIONS

This application claims priority to Provisional Application Ser. No. 60/447710 filed on Feb. 19, 2003, which is hereby incorporated by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a transmission diffraction grating element, a production method of diffraction grating element and a method of designing diffraction grating element.

2. Related Background of the Invention

Generally, a diffraction grating element is, in a transparent flat plate having a first plane and a second plane parallel to each other, formed with a diffraction grating on the first plane (see Kashiko Kodate, “Development of diffractive optics and future challenges”; Japan Women's University Journal, Faculty of Science, 10th Edition, pages 7 to 24 (2002), for example). In the diffraction grating element, for example, when light enters the first plane from a medium, which is in contact with the first plane, at a constant incident angle, the light is diffracted by the diffraction grating formed on the first plane, transmitted within the transparent flat plate, and then emitted to a medium, which is in contact with the second plane. The diffraction angle of the light, which is emitted from the second plane of the transparent flat plate, varies according to the wavelength.

Thus, the diffraction grating element may be used as an optical demultiplexer in which incident light is demultiplexed and then emitted. Also, when the light is guided in the direction opposite to the above case, the diffraction grating element may be used as an optical multiplexer in which incident light is multiplexed and then emitted. Further, by combining the diffraction grating element with another optical elements, a dispersion regulator, which regulates the group delay time of the light in accordance with the wavelength, may be constituted, for example. Accordingly, the diffraction grating element is one of the important optical elements in the wavelength division multiplexing (WDM) optical communication system, in which multiple wavelength signal light is multiplexed and then transmitted.

In the diffraction grating element, high diffraction efficiency is required. Some structural artifices for improving the diffraction efficiency have been proposed; and it is reported that about 95% diffraction efficiency has been achieved (see US Patent Application Publication No. 2002/0135876; Specification; and, Hendrick J. Gerritsen, et al., “Rectangular surface-relief transmission gratings with a very large first-order diffraction efficiency (−95%) for unpolarized light”, Applied Optics, Vol. 37, No. 25, pp. 5823–5829 (1998), for example).

SUMMARY OF THE INVENTION

However, the incident angle of the incident light, which enters the diffraction grating element, or the diffraction angle of the diffracted light, which is diffracted and then emitted from the diffraction grating element is not 0° (perpendicular to the first plane or second plane of the transparent flat plate provided with diffraction grating). Accordingly, the polarization dependence due to the reflection is generated. In addition, the diffraction grating has such structure that the index of refraction changes periodically to one direction. Accordingly, particularly, in the case where the grating period is short (for example, 2λ or less), when the angle between the periodic direction and the polarization direction changes, the diffraction efficiency changes. As described above, generally, the diffraction efficiency of the diffraction grating element has the polarization dependence; and the diffraction efficiency of TE polarized light and TM polarized light is different from each other. Particularly, when the angular dispersion of the diffraction angle is large (wavelength resolution in multiplexing/demultiplexing is high), the period becomes shorter. Accordingly, the polarization dependence becomes remarkable.

It is possible to reduce the difference in the diffraction efficiency between the TE polarized light and the TM polarized light, by appropriately designing the sectional configuration (height, width or like of the grating) of the diffraction grating so that the polarization dependence due to the reflection and the polarization dependence due to the structure are canceled. However, even when so designed as described above, it is impossible to improve the diffraction efficiency and reduce the polarization dependence of the diffraction efficiency in a wide wavelength band.

The present invention has been accomplished to solve the above-described problems. An object of the present invention is to provide a diffraction grating element capable of improving the diffraction efficiency and reducing the diffraction efficiency in a wide wavelength band by canceling the polarization dependence due to the reflection and the polarization dependence due to the structure respectively. Also, another object of the present invention is to provide a method of fabricating or designing such diffraction grating element.

A diffraction grating element in accordance with a first invention comprises, (1) given a first plane and a second plane parallel with each other, a first medium (index of refraction n₁) provided at the outer side than the first plane being in contact with the first plane, (2) a second medium (index of refraction n₂) and a third medium (index of refraction n₃, n₃<n₂) disposed alternately in a predetermined direction parallel with the first plane between the first plane and the second plane being in contact with the first plane and the second plane to constitute a diffraction grating, and (3) a fourth medium (index of refraction n₄) provided at the outer side than the second plane being in contact with the second plane. And Each of indexes of refraction n₁–n₄ of the first medium, the second medium, the third medium and the fourth medium satisfies a relational expression of “n₃<n₁<n₂, n₃≦n₄≦n₂”, or “n₃≦n₁≦n₂, n₃<n₄<n₂”. Further, the diffraction grating element is characterized in that both of the second medium and the third medium are solid; or, the first medium or the fourth medium is made of an isotropic material.

In the diffraction grating element in accordance with the first invention, between the first medium and the fourth medium, the second medium and the third medium are disposed alternately to constitute the diffraction grating. The light, which enters the diffraction grating from the first medium, is diffracted at the diffraction grating portion and output to the fourth medium. Or, the light, which enters the diffraction grating from the fourth medium, is diffracted at the diffraction grating portion and output to the first medium. In the diffraction grating element, the index of refraction of each medium satisfies the above relational expressions. Accordingly, it is possible to improve the diffraction efficiency and to reduce the polarization dependence of the diffraction efficiency in a wide wavelength band.

In the diffraction grating element in accordance with the first invention, given that an average index of refraction between the first plane and the second plane is n_(av), it is preferred that the index of refraction n₁ of the first medium satisfies a relational expression of “n_(av)−0.2≦n₁≦n_(av)+0.2”; and further, it is preferred that the index of refraction n₄ of the fourth medium satisfies a relational expression of “n_(av)−0.2≦n₄≦n_(av)+0.2”. Further, it is preferred that the thickness of the first medium with respect to a direction perpendicular to the first plane is 5 μm or more; and further, it is preferred that the thickness of the fourth medium with respect to a direction perpendicular to the first plane is 5 μm or more. These cases are further preferred for improving the diffraction efficiency and for reducing the polarization dependence of the diffraction efficiency in a wide wavelength band.

A diffraction grating element in accordance with a second invention comprises, (1) given first-fourth planes disposed parallel with each other in order, a first medium (index of refraction n₁) provided at the outer side than the first plane being in contact with the first plane, (2) a second medium (index of refraction n₂) and a third medium (index of refraction n₃, n₃<n₂) disposed alternately in a predetermined direction parallel with the first plane between the second plane and the third plane being in contact with the second plane and the third plane to constitute a diffraction grating, (3) a fourth medium (index of refraction n₄) provided at the outer side than the fourth plane being in contact with the fourth plane, (4) a fifth medium (average index of refraction n₅) provided between the first plane and the second plane being in contact with the first plane and the second plane, and (5) a sixth medium (average index of refraction n₆) provided between the third plane and the fourth plane being in contact with the third plane and the fourth plane. And, given that an average index of refraction between the second plane and the third plane is n_(av), the average index of refraction n₅ of the fifth medium satisfies a relational expression of “n₁<n₅<n_(av)” or “n_(av)<n₅<n₁”, and the average index of refraction n₆ of the sixth medium satisfies a relational expression of “n₄<n₆<n_(av)” or “n_(av)<n₆<n₄”.

In the diffraction grating element in accordance with the second invention, between the fifth medium and the sixth medium, the second medium and the third medium are disposed alternately to constitute the diffraction grating. The light, which enters the diffraction grating from the first medium, passes through the fifth medium, and is diffracted at the diffraction grating portion, and output to the fourth medium through the sixth medium. Or, the light, which enters the diffraction grating from the fourth medium, passes through the sixth medium, and is diffracted at the diffraction grating portion, and output to the first medium through the fifth medium. In the diffraction grating element, the index of refraction of each medium satisfies the above relational expressions. Accordingly, it is possible to improve the diffraction efficiency and to reduce the polarization dependence of the diffraction efficiency in a wide wavelength band.

In the diffraction grating element in accordance with the second invention, it is preferred that the index of refraction n₅ of the fifth medium satisfies a relational expression of “(n₁n_(av))^(1/2)−0.2<n₅<(n₁n_(av))^(1/2)+0.2”; and further, it is preferred that the index of refraction n₆ of the sixth medium satisfies a relational expression of “(n₄n_(av))^(1/2)−0.2<n₆<(n₄n_(av))^(1/2)+0.2”. Further, it is preferred that, given that the period of the diffraction grating is Λ; the thickness of the fifth medium with respect to a direction perpendicular to the first plane is h₅; and given that the light with wavelength λ enters the diffraction grating, the wavelength λ of the light which satisfies a relational expression of “λΛ/4(4n₅ ²Λ²−λ²)^(1/2)<h₅<3λΛ/4(4n₅ ²Λ²−λ²)^(1/2)” is present in a waveband of 1.26 μm–1.675 μm. And further, it is preferred that, given that the period of the diffraction grating is Λ; the thickness of the sixth medium with respect to a direction perpendicular to the first plane is h₆; and given that the light with wavelength λ enters the diffraction grating, the wavelength λ of the light which satisfies a relational expression of “λΛ/4(4n₆ ²Λ²−λ²)^(1/2)<h₆<3λΛ/4(4n₆ ²Λ²−λ²)^(1/2)” is present in a waveband of 1.26 μm–1.675 μm. These cases are further preferred for improving the diffraction efficiency and for reducing the polarization dependence of the diffraction efficiency in a wide wavelength band.

Further, it is preferred that the fifth medium is made of a plurality of media disposed alternately in a predetermined direction. And further, it is preferred that the sixth medium is made of a plurality of media disposed alternately in a predetermined direction. In this case, it is possible to improve the diffraction characteristics as well as it is preferred for producing the diffraction grating element.

A diffraction grating element in accordance with a third invention comprises, (1) given first-third planes disposed parallel with each other in order, a first medium (index of refraction n₁) provided at the outer side than the first plane being in contact with the first plane, (2) a second medium (index of refraction n₂) and a third medium (index of refraction n₃, n₃<n₂) disposed alternately in a predetermined direction parallel with the first plane between the second plane and the third plane being in contact with the second plane and the third plane to constitute a diffraction grating, (3) a fourth medium (index of refraction n₄) provided at the outer side than the third plane being in contact with the third plane, and (5) a fifth medium (average index of refraction n₅) provided between the first plane and the second plane being in contact with the first plane and the second plane. And, given that the average index of refraction between the second plane and the third plane is n_(av), the average index of refraction n₅ of the fifth medium satisfies a relational expression of “n₁<n₅<n_(av)” or “n_(av)<n₅<n₁”.

In the diffraction grating element in accordance with the third invention, between the fourth medium and the fifth medium, the second medium and the third medium are disposed alternately to constitute the diffraction grating. The light, which enters the diffraction grating from the first medium, passes through the fifth medium, and is diffracted at the diffraction grating portion, and output to the fourth medium. Or, the light, which enters the diffraction grating from the fourth medium, is diffracted at the diffraction grating portion and output to the first medium through the fifth medium. In the diffraction grating element, the index of refraction of each medium satisfies the above relational expression. Accordingly, it is possible to increase the diffraction efficiency and to improve the polarization dependence of the diffraction efficiency in a wide wavelength band.

In the diffraction grating element in accordance with the third invention, it is preferred that the index of refraction n₅ of the fifth medium satisfies a relational expression of “(n₁n_(av))^(1/2)−0.2<n₅<(n₁n_(av))^(1/2)+0.2”. Further, given that the period of the diffraction grating is Λ; the thickness of the fifth medium with respect to a direction perpendicular to the first plane is h₅; and given that the light with wavelength λ enters the diffraction grating, the wavelength λ of the light which satisfies a relational expression of “λΛ/4(4n₅ ²Λ²−λ²)^(1/2)<h₅<3λΛ/4(4n₅ ²Λ²−λ²)^(1/2)” is present in a waveband of 1.26 μm–1.675 μm. It is preferred that each index of refraction n₂–n₄ of the second medium, the third medium and the fourth medium satisfies a relational expression of “n₃<n₄<n₂”. It is preferred that the index of refraction n₄ of the fourth medium satisfies a relational expression of “n_(av)−0.2≦n₄≦n_(av)+0.2”. Further, it is preferred that the thickness of the fourth medium with respect to a direction perpendicular to the first plane is 5 μm or more. These cases are further preferred for improving the diffraction efficiency and for reducing the polarization dependence of the diffraction efficiency in a wide wavelength band.

It is preferred that the fifth medium is made of a plurality of media disposed alternately in a predetermined direction. In this case, it is possible to improve the diffraction characteristics as well as it is preferred for producing the diffraction grating element.

A diffraction grating element in accordance with a fourth invention comprises a base plate, a first reflection-inhibiting portion provided on the base plate, a diffraction grating portion provided on the first reflection-inhibiting portion, and a second reflection-inhibiting portion provided on the diffraction grating portion, wherein the second reflection-inhibiting portion is in contact with a first medium, in the diffraction grating portion, a second medium and a third medium are disposed alternately in a predetermined direction parallel with the base plate to constitute a diffraction grating, and in a waveband of 1.26 μm–1.675 μm, a wavelength of which reflectance is 10% or less is present. According to this diffraction grating element, it is possible to increase the diffraction efficiency and to reduce the polarization dependence of the diffraction efficiency in a wide wavelength band.

In the diffraction grating element in accordance with a fourth invention, a diffraction capacity of the diffraction grating portion is larger than 50% of the entire diffraction capacity including the diffraction grating portion, the first reflection-inhibiting portion and the second reflection-inhibiting portion. It is preferred that the modulation of the index of refraction of the diffraction grating portion is larger than the modulation of the index of refraction of the first reflection-inhibiting portion and the second reflection-inhibiting portion. Also, it is preferred that the maximum refraction of the diffraction grating portion is larger than the index of refraction of the base plate and the first medium. Further, it is preferred that the period of the diffraction grating is 1.675 μm or less.

In the diffraction grating element in accordance with the first-fourth inventions, it is preferred that a wavelength of the light, in which the diffraction efficiency of the TE polarized light and the TM polarized light is 90% or more, respectively, is present. Also, it is preferred that a wavelength of the light, in which the difference of the diffraction efficiency between the TE polarized light and the TM polarized light is 5% or less, is present. In these cases, in an optical communication system that multiplexes and transmits signal light with multiple wavelengths, this diffraction grating element can be appropriately used.

In the diffraction grating element in accordance with the first-fourth inventions, it is preferred that the difference between the index of refraction n₂ of the second medium and the index of refraction n₃ of the third medium is 0.7 or more. It is preferred that the second medium is made of any one of TiO₂, Ta₂O₅ and Nb₂O₅; and the third medium is constituted of a gas. In these cases, since the height of the diffraction grating portion can be reduced, the diffraction grating element can be produced easily.

In the diffraction grating element in accordance with the first-fourth inventions, it is preferred that the second medium or the third medium are made of a predetermined material of which index of refraction changes by an irradiation of energy beam; and it is preferred that the predetermined material is a diamond-like carbon. In these cases, the diffraction grating element with desired characteristics can be produced easily.

It is preferred that, in the diffraction grating element in accordance with the first invention, the first medium or the fourth medium is made of a predetermined material of which etching rate is slower than that of the second medium or the third medium. It is preferred that, in the diffraction grating element in accordance with the second invention, the fifth medium or the sixth medium is made of a predetermined material of which etching rate is slower than that of the second medium or the third medium. In the second invention, when the fifth medium or sixth medium is subjected to the etching, it is preferred that the first medium or the fourth medium is made of a predetermined material of which etching rate is slow. Further, it is preferred that, in the diffraction grating element in accordance with the third invention, the fourth medium or the fifth medium is made of a predetermined material of which etching rate is slower than that of the second medium or the third medium. In the third invention, when the fifth medium is subjected to the etching, it is preferred that the first medium is made of a predetermined material of which etching rate is slow. As described above, it is preferred that, for a non-etching layer, which is in contact with an etching layer, a material of which etching rate is slow; for example; it is preferred that the ratio of the etching rate is twice or more is used. Here, it is preferred that the above-described predetermined materials are any of Al₂O₃, MgO, Nd₂O₃ and a fluorinated compound; and it is preferred that the second medium or the third medium is any of TiO₂, Nb₂O₅, Ta₂O₅, SiN, SiO₂, SiO, ZrO₂ and Sb₂O₃. These cases are preferable for producing the diffraction grating element by etching.

A production method of a diffraction grating element in accordance with the present invention is a production method of the diffraction grating element in accordance with the above-described first-fourth inventions. The method comprises the steps of: forming a layer constituted of a predetermined material of which index of refraction changes by an irradiation of an energy beam; and irradiating an energy beam onto the layer with a spatial strength modulation pattern to form a diffraction grating, in which the second medium and the third medium with an index of refraction different from each other, are disposed alternately in the layer. Or, the method comprises the steps of: forming a layer formed of a predetermined material; and performing an etching on the layer with a predetermined spatial pattern to form a diffraction grating, in which the second medium and the third medium with an index of refraction different from each other, are disposed alternately in the layer.

A designing method of the diffraction grating element of the present invention is a designing method of a diffraction grating element having a diffraction grating portion of which index of refraction changes periodically in a predetermined direction and a reflection-inhibiting portion on at least one of the top and the bottom of the diffraction grating portion, comprising the steps of determining so that each of the diffraction grating portion and the reflection-inhibiting portion is formed with a film having an average index of refraction by the media included therein respectively, setting the phase change of light at the diffraction grating portion to 90°, and deriving refraction distribution of the diffraction grating element so that the reflectance is 10% or less at a desired wavelength. According to the designing method of the diffraction grating element, result of analysis can be obtained close to the characteristics of an actually produced diffraction grating element. Accordingly, the diffraction grating element can be designed easily.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an explanatory diagram of a diffraction grating element 10 in accordance with a first embodiment.

FIG. 2 is a graph showing the diffraction characteristics of the diffraction grating element 10 in accordance with an example 1.

FIG. 3 is a graph showing the diffraction characteristics of a diffraction grating element in accordance with a comparative example 1.

FIG. 4 is a graph showing a relationship between the diffraction efficiency of the diffraction grating element 10 in accordance with example 1 and the index of refraction n₄ of a fourth medium 14.

FIG. 5 is an explanatory diagram of a diffraction grating element 10A in accordance with a modified example 1.

FIG. 6 is an explanatory diagram of a diffraction grating element 10B in accordance with a modified example 2.

FIG. 7 is an explanatory diagram of a diffraction grating element 20 in accordance with a second embodiment.

FIG. 8 is a graph showing the diffraction characteristics of the diffraction grating element 20 in accordance with an example 2.

FIG. 9 is an explanatory diagram of a diffraction grating element 20A in accordance with a modified example.

FIG. 10 is an explanatory diagram of a diffraction grating element 20B in accordance with an example 3.

FIG. 11 is a graph showing the diffraction characteristics of the diffraction grating element 20B in accordance with an example 3.

FIG. 12 is an explanatory diagram of a diffraction grating element 30 in accordance with a third embodiment.

FIG. 13 is an explanatory diagram of a diffraction grating element 30A in accordance with an example 4.

FIG. 14 is a graph showing the diffraction characteristics of the diffraction grating element 30A in accordance with an example 4.

FIG. 15 is an explanatory diagram of a diffraction grating element 40 in accordance with a fourth embodiment.

FIG. 16 is a graph showing the characteristics of the zero-order reflection diffraction efficiency of the diffraction grating element in accordance with the fourth embodiment and the zero-order reflection diffraction efficiency of the equivalent model.

FIG. 17 is an explanatory diagram of a diffraction grating element 40A in accordance with an example 5.

FIG. 18 is an explanatory diagram of a diffraction grating element 40B in accordance with an example 6.

FIG. 19 is a graph showing the diffraction efficiency of the diffraction grating element in accordance with the fourth embodiment.

FIG. 20 is a graph showing the aspect ratio of grooves in the diffraction grating element in accordance with the fourth embodiment.

FIG. 21 is a graph showing the tolerance of groove depth in the diffraction grating element in accordance with the fourth embodiment.

FIG. 22 is an explanatory diagram of a diffraction grating element 30B in accordance with a mode of modification.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring to the accompanying drawings, embodiments of the present intention will be described in detail. The same reference symbols have been assigned to the same elements or parts in the description of the drawings, and repetitive description is omitted.

FIRST EMBODIMENT

First of all, a first embodiment of a diffraction grating element in accordance with the present invention will be described. FIG. 1 is an explanatory diagram of a diffraction grating element 10 in accordance with the first embodiment. The diagram shows a section of the diffraction grating element 10 when the same is cut off at a plane perpendicular to the grating. The diffraction grating element 10 shown in the diagram comprises a first medium 11, a second medium 12, a third medium 13 and a fourth medium 14.

In this diffraction grating element 10, a first plane P₁ and a second plane P₂, which are parallel to each other, are assumed. Here, the first medium 11 is provided at the outer side than the first plane P₁ (upper side in the diagram) being in contact with the first plane P₁. Between the first plane P₁ and the second plane P₂, the second medium 12 and the third medium 13 are disposed alternately in a predetermined direction parallel to the first plane P₁ being in contact with the first plane P₁ and the second plane P₂ so as to constitute a diffraction grating. Also, the fourth medium 14 is provided at the outer side than the second plane P₂ (lower side in the diagram) being in contact with the second plane P₂. Both of the second medium 12 and the third medium 13 are solid respectively; or, the first medium 11 or the fourth medium 14 is made of an isotropic material.

In the diffraction grating element 10, between the first medium 11 and the fourth medium 14, the second medium 12 and the third medium 13 are provided alternately to form a diffraction grating. The light Li (incident angle θ), which enters the diffraction grating from the first medium 11, is diffracted at the diffraction grating portion and emitted to the fourth medium 14 (in FIG. 1, zero-order light Ld₀ and first-order diffracted light Ld₁ are shown). Or, the light, which enters the diffraction grating from the fourth medium 14, is diffracted at the diffraction grating portion, and emitted to the first medium 11.

Each region in the second medium 12 and the third medium 13 has a region of which section is rectangular. In the diffraction grating portion constituted of the diffraction grating, which is formed of the second medium 12 and the third medium 13 being disposed in a predetermined direction alternately, given that the period of the diffraction grating is Λ; and the ratio that the second medium 12 occupies in the period Λ (duty ratio) is f. Given that the distance between the first plane P₁ and the second plane P₂ (i.e., height of the grating) is H. Given that the index of refraction of the first medium 11 is n₁; the index of refraction of the second medium 12 is n₂; the index of refraction of the third medium 13 is n₃ (n₃<n₂); and the index of refraction of the fourth medium 14 is n₄.

Here, the average index of refraction n_(av) of the diffraction grating portion between the first plane P₁ and the second plane P₂ is expressed by the following expression: n _(av) =√{square root over (fn ² ² +(1−f)n ³ ² )}  (1) Also, the average index of refraction n_(av) is between the index of refraction n₂ of the second medium 12 and the index of refraction n₃ of the third medium 13, and satisfies the following relational expression: n₃<n_(av)<n₂  (2)

In the case where the period Λ of the diffraction grating is equal to the order or less (for example, 2λ or less) of the wavelength λ of the incident light, when considering the reflection of the light at the first plane P₁ and the second plane P₂ respectively, the portion between the first plane P₁ and the second plane P₂ may be replaced with a medium having a uniform index of refraction n_(av). Here, when the index of refraction n₁ of the first medium 11 or the index of refraction n₄ of the fourth medium 14 is closer to the average index of refraction n_(av) of the diffraction grating portion, the more reflection at the first plane P₁ or the second plane P₂ is reduced and the diffraction characteristics are improved.

Accordingly, in this embodiment, the indexes of refraction n₁–n₄ of each medium satisfy the following relational expression: n₃<n₁<n₂, n₃≦n₄≦n₂   (3a), or n₃≦n₁≦n₂, n₃<n₄<n₂   (3b) Further, the indexes of refraction n₁–n₄ of each medium preferably satisfy the following relational expression: n_(av)−0.2≦n₁≦n_(av)+0.2   (4a) , or n_(av)−0.2≦n₄≦n_(av)+0.2   (4b).

In accordance with the above expression (3) or expression (4), the indexes of refraction n₁–n₄ of each medium are determined; and then, the diffraction characteristics of the diffraction grating element 10 is analyzed by means of the rigorous coupled-wave analysis (RCWA). The duty ratio f, the grating period Λ and the height of the grating H are optimized by means of an optimizing technique (for example, nonlinear programming, simulated annealing, genetic algorithm or the like). Thereby, the diffraction grating element 10 with satisfactory diffraction characteristics is designed.

Next, examples of the diffraction grating element 10 in accordance with the first embodiment will be described along with a comparative example. In the diffraction grating element 10 of an example 1, the first medium 11 and the fourth medium 14 are constituted of a silica glass respectively (n₁=n₄=1.45); the index of refraction n₂ of the second medium 12 is 1.75; the third medium 13 is constituted of air (n₃=1); the duty ratio f is 0.70; the grating period Λ is 1.01 μm; and the height of the grating H is 2.26 μm. In the diffraction grating element of a comparative example 1, the first medium and the third medium are constituted of air respectively (n₁=n₃=1); the second medium and the fourth medium are constituted of silica glass respectively (n₂=n₄=1.45); the duty ratio f is 0.84; the grating period Λ is 1.01 μm; and the height of the grating H is 6.02 μm.

FIG. 2 is a graph showing the diffraction characteristics of the diffraction grating element 10 of an example 1. FIG. 3 is a graph showing the diffraction characteristics of the diffraction grating element of a comparative example 1. In these diagrams, the wavelength dependence of the diffraction efficiency when the incident angle θ of the light is the Bragg incident angle at the wavelength of 1.55 μm is shown with respect to TE polarized light and TM polarized light respectively. The wording “Bragg incident angle” means the incident angle in which the respective angles of the zero-order light and the first-order light are equal to each other. In these example 1 and comparative example 1, the parameter was designed so that, at waveband of 1.52 μm–1.57 μm, the polarization dependence and the wavelength dependence of the diffraction efficiency become as small as possible; and the diffraction efficiency becomes as large as possible.

As demonstrated in these diagrams being compared with each other, compared with the case of comparative example 1 (FIG. 3), in the case of example 1 (FIG. 2), in a wide wavelength band, the diffraction efficiency of the TE polarized light and the TM polarized light are high as 95% or more; and the difference of the diffraction efficiency between the TE polarized light and the TM polarized light was 2% or less. Thus, the diffraction grating element 10 in accordance with this embodiment can improve the diffraction efficiency and reduce the polarization dependence of the diffraction efficiency in a wide wavelength band.

FIG. 4 is a graph showing a relationship between the diffraction efficiency of the diffraction grating element 10 and the index of refraction n₄ of the fourth medium 14 of the example 1. Here, the wavelength λ was fixed to 1.55 μm. As demonstrated in the diagram, when the index of refraction n₄ of the fourth medium 14 satisfies the relational expression of the above expression (4b), the diffraction efficiency is large, and the polarization dependence is small.

Next, several production methods of the diffraction grating element 10 in accordance with the first embodiment will be described.

In the first production method, a layer of the second medium 12 is formed on the fourth medium 14; on that layer, grooves with a predetermined spatial pattern are formed by etching; and the first medium 11 is laminated thereon. In this case, groove regions, which are formed by the etching, are the third medium 13 constituted of air. Or, in the groove regions, which are formed by the etching, another material, which will serve as the third region 13, is embedded by means of CVD (Chemical Vapor Deposition) or the like; and then, the height of the second region 12 and the third region 13 is aligned with each other by means of polishing or the like, and the first medium 11 may be formed thereon. Here, in the case where both of the second region 12 and the third region 13 are solid, it is possible to prevent a shape of the grooves from being deformed due to the pressure when being laminated to the first medium 11. And further, when the first medium 11 is formed by means of the CVD or the like, it is preferably possible to prevent the first medium 11 from entering the grooves. On the surface of the fourth medium 14, a layer of, not the second medium 12 but the third medium 13, may be formed.

When the layer, which is constituted of the second medium 12 or third medium 13, is subjected to the etching, it is preferred that the fourth medium 14 is constituted of a predetermined material, of which etching rate is slower than that of the second medium 12 or third medium 13. In such case, it is possible to terminate the etching at the upper surface of the fourth medium 14 (second plane P₂). From the above viewpoint, it is preferred that, for example, the fourth medium 14 is constituted of any one of Al₂O₃, MgO, Nd₂O₃ and fluorinated compound (AlF₃, MgF₂, CaF₂, NdF₃ or the like). Also, it is preferred that the second medium 12 or the third medium 13 is constituted of any one of TiO₂, Nb₂O₅, Ta₂O₅, SiN, SiO₂, SiO, ZrO₂ and Sb₂O₃.

In place of the above etching, the second medium 12 and the third medium 13 may be formed alternately by means of lift-off or the like.

In any case of the etching and the lift-off, the lower height of the grating H allows the easier forming of the grooves. In the first embodiment, the index of refraction n₁–n₄ of each medium can be arranged separately. Accordingly, the difference (n₂–n₃) between the index of refraction n₂ of the second medium 12 and the index of refraction n₃ of the third medium 13 can be made large; thus the height of the grating H can be made lower. From the above viewpoint, when the difference (n₂–n₃) between the index of refraction n₂ of the second medium 12 and the index of refraction n₃ of the third medium 13 is 0.7 or more, the height of the grating H can be 3 μm or less; thus the fabricating thereof is preferably made easier. Therefore, to achieve the above, the second medium 12 is preferably formed of any one of TiO₂, Ta₂O₅ and Nb₂O₅, and the third medium 13 is preferably constituted of a gas. When both of the second medium and the third medium are solid, as the third medium, a material with low index of refraction such as MgF₂ (index of refraction 1.35) is used; and as the second medium, a material with high index of refraction such as a semiconductor, for example, Si (index of refraction 3.5) is further preferably used.

In the second production method, on the surface of the fourth medium 14, a layer constituted of a predetermined material, of which index of refraction can be changed by an irradiation of an energy beam. (for example, X-ray, corpuscular beam or the like), is formed. Onto the layer, the energy beam is irradiated with a predetermined spatial strength-modulating pattern. In that layer, a diffraction grating formed of the second medium 12 and the third medium 13 disposed alternately, which have the index of refraction different from each other, is formed; and the first medium 11 is formed thereon. Or, on a layer of a predetermined material, the first medium 11 is formed, and then, the energy beam is irradiated onto the layer using a predetermined spatial strength modulating pattern to preferably form the diffraction grating, in which the second medium 12 and the third medium 13, which have the index of refraction different from each other, are disposed alternately on the layer.

As the predetermined material, of which index of refraction can be changed by an irradiation of energy beam, a diamond-like carbon (DLC) is preferably used. In this case, as the energy beam, which is irradiated to change the index of refraction of the diamond-like carbon, a synchrotron radiation (SR light) or hydrogen ion beam is used. The index of refraction of the region of the diamond-like carbon, where is irradiated with the energy beam, becomes larger. That is, the region, where is not subjected to the irradiation of the energy beam, serves as the third medium 13 (index of refraction n₃), and the region, where has been subjected to the irradiation of the energy beam, serves as the second medium 12 (index of refraction n₂).

Compared to the first production method, the second production method is preferred in a point that the fabricating of the diffraction grating element 10 is simple. Further, in the first production method, it is difficult to form the configuration of the section of the grooves, which is formed with the etching, into a perfect rectangle. Contrary to this, in the second production method, it is preferred in the point that each sectional configuration of the regions of the second medium 12 and the third medium 13 can be formed into a further complete rectangle.

Next, modified examples of the diffraction grating element 10 in accordance with the first embodiment will be described. FIG. 5 is an explanatory diagram of a diffraction grating element 10A in accordance with a modified example 1. In the diffraction grating element 10A in accordance with the modified example 1 shown in the diagram, compared with the constitution of the above-described diffraction grating element 10, at the outer side (upper side in the diagram) of the first medium 11 (index of refraction n₁), a reflection reducing film 11 a is formed; and further, at the outside of the reflection reducing film 11 a, there resides a medium 11 b (index of refraction n₀); also, at the outside (lower side in the diagram) of the fourth medium 14 (index of refraction n₄), a reflection reducing film 14 a is formed; and further, at the outside of the reflection reducing film 14 a, there resides a medium 14 b (index of refraction n₅). For example, the outside medium 11 b and medium 14 b is constituted of air, or an optical glass for controlling the linear expansion coefficient of the entire diffraction grating element 10A for reducing the temperature dependence of the optical characteristics.

In the diffraction grating element 10A of the modified example 1, in order to allow the evanescent wave, which is generated in the diffraction grating, to be satisfactorily attenuated, it is preferred that each thickness of the first medium 11 and the fourth medium 14 (thickness with respect to the direction perpendicular to the first plane P₁) is satisfactorily thicker than the wavelength λ. For example, when the wavelength λ is 1.55 μm, each thickness of the first medium 11 and the fourth medium 14 is preferably 5 μm or more. Also, between the first medium 11 and the outer medium 11 b, the reflection reducing film 11 a is provided; and between the fourth medium 14 and the outer medium 14 b, the reflection reducing film 14 a is provided. Accordingly, the reflection at the boundary face therebetween is reduced, and thus, the diffraction characteristics are prevented from being degraded.

Here, when the first medium 11 or the fourth medium 14 is constituted of an isotropic material, since the polarization mode dispersion occurs, or the state of the polarization changes, an influence is rendered on the optical communication. However, by forming the first medium 11 and the fourth medium 14 with an isotropic material, these influences can be reduced. Further, the design for reducing the reflection at the reflection reducing film 11 a and the reflection reducing film 14 a can be made easily.

FIG. 6 is an explanatory diagram of a diffraction grating element 10B in accordance with a modified example 2. In FIG. 6, an example of each locus of an incident light Li, a reflected light Lr from the boundary between the fourth medium 14 and the medium 14 b and diffraction light Ld is shown. Compared with the constitution of the above-described diffraction grating element 10, in the diffraction grating element 10B of the modified example 2 shown in the diagram, the medium 11 b (index of refraction n₀) resides at the outside (upper side in the diagram) of the first medium 11 (index of refraction n₁); and the medium 14 b (index of refraction n₅) is resides at the outside (lower side in the diagram) of the fourth medium 14 (index of refraction n₄). For example, the outside medium 11 b and the medium 14 b are constituted of air or an optical glass for controlling the linear expansion coefficient of the entire diffraction grating element 10A to reduce the temperature dependence of the optical characteristics. Particularly, in the diffraction grating element 10B of the modified example 2, in order to prevent the reflected light, the transmitted light and the diffraction light, at the diffraction grating portion, from entering the diffraction grating portion again, each of the first medium 11 and the fourth medium 14 has a satisfactory thickness. Owing to this, the diffraction characteristics are prevented from being degraded.

SECOND EMBODIMENT

Next, a second embodiment of a diffraction grating element in accordance with the present invention will be described. FIG. 7 is an explanatory diagram of a diffraction grating element 20 in accordance with a second embodiment. The diagram shows a section of the diffraction grating element 20 when the same is cut off at a plane perpendicular to the grating. The diffraction grating element 20 shown in the diagram comprises a first medium 21, a second medium 22, a third medium 23, a fourth medium 24, a fifth medium 25 and a sixth medium 26.

In this diffraction grating element 20, a first plane P₁, a second plane P₂, a third plane P₃ and fourth plane P₄, which are parallel to each other and aligned in order, are assumed. Here, the first medium 21 is provided at the outer side than the first plane P₁ (upper side in the diagram) being in contact with the first plane P₁. Between the second plane P₂ and the third plane P₃, the second medium 22 and the third medium 23 are disposed alternately in a predetermined direction parallel to the first plane P₁ being in contact with the second plane P₂ and the third plane P₃ so as to form a diffraction grating. The fourth medium 24 is provided at the outer side than the fourth plane P₄ (lower side in the diagram) being in contact with the fourth plane P₄. The fifth medium 25 is provided between the first plane P₁ and the second plane P₂ being in contact with the first plane P₁ and the second plane P₂. The sixth medium 26 is provided between the third plane P₃ and the fourth plane P₄ being in contact with the third plane P₃ and the fourth plane P₄.

In the diffraction grating element 20, between the fifth medium 25 and the sixth medium 26, the second medium 22 and the third medium 23 are disposed alternately to form a diffraction grating. The light, which enters the diffraction grating from the first medium 21, passes through the fifth medium 25 and is diffracted at the diffraction grating portion, and emitted to the fourth medium 24 through the sixth medium 26. Or, the light, which enters the diffraction grating from the fourth medium 24, passes through the sixth medium 26 and is diffracted at the diffraction grating portion, and emitted to the first medium 21 through the fifth medium 25.

Each region in the second medium 22 and the third medium 23 has a rectangular section. In the diffraction grating portion constituted of the diffraction grating, which is formed of the second medium 22 and the third medium 23 disposed alternately in a predetermined direction, it is assumed that the period of the diffraction grating is Λ; the ratio that the second medium 22 occupies in the period Λ (duty ratio) is f. It is assumed that the distance between the first plane P₁ and the second plane P₂ (i.e., thickness of the fifth medium 25) is h₅. It is assumed that the distance between the second plane P₂ and the third plane P₃ (i.e., height of the grating) is H. It is assumed that the distance between the third plane P₃ and the fourth plane P₄ (i.e., thickness of the sixth medium 26) is h₆. It is assumed that index of refraction of the first medium 21 is n₁; the index of refraction of the second medium 22 is n₂; the index of refraction of the third medium 23 is n₃ (n₃<n₂); the index of refraction of the fourth medium 24 is n₄; the index of refraction of the fifth medium 25 is n₅; and the index of refraction of the sixth medium 26 is n₆.

Here, the average index of refraction n_(av) of the diffraction grating portion between the second plane P₂ and the third plane P₃ is expressed by the above expression (1). Also, between the index of refraction n₂ of the second medium 22 and the index of refraction n₃ of the third medium 23, the average index of refraction n_(av) satisfies the above relational expression (2).

Each of the fifth medium 25 and the sixth medium 26 may be a multi-layered film for reducing the reflection, or may be a film of single layer. In the case of the film of single layer, the index of refraction n₅ of the fifth medium 25 satisfies the following relational expression: n₁<n₅<n_(av) or n_(av)<n₅<n₁  (5). The index of refraction n₆ of the sixth medium 26 satisfies the following relational expression: n ₄<n₆<n_(av) or n_(av)<n₆<n₄  (6). The diffraction grating element 20 in accordance with this embodiment is arranged as described above; thereby the reflection at each boundary face is reduced, and the diffraction characteristics are prevented from being degraded.

Further, it is preferred that the index of refraction n₅ of the fifth medium 25 satisfies the following relational expression: √{square root over (n ₁ n _(av))}−0.2<n ₅ <√{square root over (n ¹ n _(av) )}+0.2  (7) Also, it is preferred that the index of refraction n₆ of the sixth medium 26 satisfies the following relational expression: √{square root over (n ₄ n _(av))}−0.2<n ₆ <√{square root over (n ⁴ n _(av) )}+0.2  (8)

Further, to reduce the reflection at the boundary face in a wide waveband, it is preferred that each of the height h₅ of the fifth medium 25 and the height h₆ of the sixth medium 26 are equal to or less than the wavelength order. For example, 5 μm or less is preferred.

Particularly, given that the angle of the light with a wavelength λ in the fifth medium 25 is θ₅, it is preferred that the thickness h₅ of the fifth medium 25 satisfies the following relational expression: $\begin{matrix} {{\frac{1}{2} \cdot \frac{\lambda}{4\; n_{5}\cos\;\theta_{5}}} < h_{5} < {\frac{3}{2} \cdot \frac{\lambda}{4\; n_{5}\cos\;\theta_{5}}}} & (9) \end{matrix}$ Also, given that the angle of the light with a wavelength λ in the sixth medium 26 is θ₆, it is preferred that the thickness h₆ of the sixth medium 26 satisfies the following relational expression: $\begin{matrix} {{\frac{1}{2} \cdot \frac{\lambda}{4\; n_{6}\cos\;\theta_{6}}} < h_{6} < {\frac{3}{2} \cdot \frac{\lambda}{4\; n_{6}\cos\;\theta_{6}}}} & (10) \end{matrix}$

Further, given that the light enters at Bragg angle, the above expression (9) is expressed by the following expression: $\begin{matrix} {\frac{\lambda\;\Lambda}{4\sqrt{{4\; n_{5}^{2}\Lambda^{2}} - \lambda^{2}}} < h_{5} < \frac{3\lambda\;\Lambda}{4\sqrt{{4\; n_{5}^{2}\Lambda^{2}} - \lambda^{2}}}} & (11) \end{matrix}$ The above expression (10) is expressed by the following expression: $\begin{matrix} {\frac{\lambda\;\Lambda}{4\sqrt{{4\; n_{6}^{2}\Lambda^{2}} - \lambda^{2}}} < h_{6} < \frac{3\lambda\;\Lambda}{4\sqrt{{4\; n_{6}^{2}\Lambda^{2}} - \lambda^{2}}}} & (12) \end{matrix}$ The above expression (11) and expression (12) are derived assuming Bragg incident angle. However, if not Bragg incident angle, the above expressions are approximately applicable.

In accordance with any of the above expressions (5)–(12), the index of refraction n₁–n₆ and the thickness h₅, h₆ of each medium are determined. After that, the diffraction characteristics of the diffraction grating element 20 are analyzed by means of the RCWA. The duty ratio f, the grating period Λ and the height H of the grating are optimized by means of the optimizing technique; thereby the diffraction grating element 20 with satisfactory diffraction characteristics is designed.

The above description has been made assuming that each of the fifth medium 25 and the sixth medium 26 is constituted of a uniform film of a single layer. However, the fifth medium 25 or the sixth medium 26 may be constituted of a multi-layered film for reducing the reflection. In the case of multi-layered film, the reflection of the TE polarized light and the TM polarized light is controlled respectively and the diffraction efficiency is improved. Further, by utilizing the polarization dependence of the multi-layered film, the polarization dependence of the diffraction efficiency can be reduced. Furthermore, it is expected that the reflection of the high order diffraction light and the evanescent wave be also reduced.

Next, examples of the diffraction grating element 20 in accordance with of the second embodiment will be described. In the diffraction grating element 20 of the example 2, the first medium 21 was constituted of air (n₁=1); the second medium 22 was a SR-light irradiated portion of the DLC (n₂=2.15); the third medium 23 was a SR-light non-irradiated portion of the DLC (n₃=1.55); the fourth medium 24 was constituted of silica glass (n₄=1.45); the fifth medium 25 was constituted of silica glass (n₅=1.45); and the sixth medium 26 was constituted of MgO (n₆=1.70). The duty ratio f was 0.74; the grating period Λ was 1.01 μm; the height H of the grating was 3.35 μm; the thickness h₅ of the fifth medium 25 was 0.30 μm; and the thickness h₆ of the sixth medium 26 was 0.23 μm.

FIG. 8 is a graph showing the diffraction characteristics of the diffraction grating element 20 of the example 2. In the diagram, the wavelength dependence of the diffraction efficiency when the incident angle θ of the light is the Bragg incident angle at a wavelength of 1.55 μm is shown with respect to the TE polarized light and the TM polarized light, respectively. Each parameter was designed so that the polarization dependence and the wavelength dependence of the diffraction efficiency was as small as possible, and the diffraction efficiency was as large as possible at a waveband of 1.52 μm–1.57 μm. As demonstrated in the diagram, in the case of the example 2 also, the diffraction efficiency of the TE polarized light and the TM polarized light were high as 95% or more, respectively, in a wide wavelength band. The difference of the diffraction efficiency between the TE polarized light and the TM polarized light was 2% or less. As described above, in the diffraction grating element 20 in accordance with this embodiment, it is possible to improve the diffraction efficiency and to reduce the polarization dependence of the diffraction efficiency in a wide wavelength band.

Next, a production method of the diffraction grating element 20 in accordance with the second embodiment will be described. Same as the case of the first embodiment, the diffraction grating element 20 in accordance with the second embodiment can be fabricated in accordance with the first production method, in which etching or lift-off is used, and the second production method using a predetermined material of which index of refraction can be changed by a radiation of an energy beam. In the second embodiment, it is preferred that the sixth medium 26 is constituted of a predetermined material of which etching rate is slower than that of the second medium 22 or third medium 23; any one of Al₂O₃, MgO, Nd₂O₃ and fluorinated compound (AlF₃, MgF₂, CaF₂, NdF₃ or the like) is preferred.

Next, a modified example of the diffraction grating element 20 in accordance with the second embodiment will be described. In the modified example of the diffraction grating element 20, both or any one of the fifth medium 25 and sixth medium 26 is comprised of a plurality of media, which are disposed alternately in a predetermined direction.

FIG. 9 is an explanatory diagram of a diffraction grating element 20A in accordance with a modified example. Compared with the constitution of the above-described diffraction grating element 20, both of the fifth medium 25 and the sixth medium 26 of the diffraction grating element 20A of the modified example shown in the diagram are constituted of a plurality of media, which are disposed alternately in a predetermined direction. Here, the predetermined direction is the same direction where the second medium 22 and the third medium 23 are disposed alternately.

The fifth medium 25 is constituted of a medium 25 a (index of refraction n_(5a)) and a medium 25 b (index of refraction n_(5b)) being disposed alternately at Λ₅. The sixth medium 26 is constituted of a medium 26 a (index of refraction n_(6a)) and a medium 26 b (index of refraction n_(6b)) being disposed alternately at Λ₆. It is assumed that the ratio (duty ratio) that the medium 25 a occupies the fifth medium 25 at period Λ₅ is f₅; and it is assumed that the ratio (duty ratio) that the medium 26 a occupies the fifth medium 26 at period Λ₆ is f₆. It is preferred that each of the period Λ₅ of the fifth medium 25 and the period Λ₆ of the sixth medium 26 is equal to the period Λ of the diffraction grating portion constituted of the second medium 22 and the third medium 23, or, equal to the period Λ divided by an integer. Further, it is preferred that each of the period Λ₅ of the fifth medium 25 and the period Λ₆ of the sixth medium 26 is satisfactorily smaller than the wavelength λ of the incident light; preferably, for example, ⅕ of the wavelength λ or less.

Here, the average index of refraction n₅ of the fifth medium 25 is expressed by the following expression: n ₅ =√{square root over (f ⁵ n _(5a) ² +(1−f ⁵ )n _(5b) ² )}  (13) The average index of refraction n₆ of the sixth medium 26 is expressed by the following expression: n ₆ =√{square root over (f ⁶ n _(6a) ² +(1−f ⁶ )n _(6b) ² )}  (14) By using the average indexes of refraction n₅ and n₆, which are expressed by the above expression (13) and expression (14), it is possible to discuss same as the above-described diffraction grating element 20 (FIG. 7).

Next, an example of the diffraction grating element 20 of the modified example will be described. FIG. 10 is an explanatory diagram of a diffraction grating element 20B in accordance with an example 3. In the diffraction grating element 20B of the example 3, the fifth medium 25 is constituted of two media 25 a and 25 b disposed alternately in a predetermined direction, and the sixth medium 26 is uniform. In the diffraction grating element 20B of the example 3, the first medium 21 was constituted of air (n₁=1); the second medium 22 was formed of Ta₂O₅ (n₂=2.0); the third medium 23 was constituted of air (n₃=1); the fourth medium 24 was formed of silica glass (n₄=1.45); in the fifth medium 25, the medium 25 a was formed of silica glass (n_(5a)=1.45), and the medium 25 b was constituted of air (n_(5b)=1); and the sixth medium 26 was formed of Al₂O₃ (n₆=1.60). The duty ratio f and f₅ were 0.66; the grating period Λ was 1.01 μm; the height H of the grating was 1.49 μm; the thickness h₅ of the fifth medium 25 was 0.36 μm; and the thickness h₆ of the sixth medium 26 was 0.34 μm.

FIG. 11 is a graph showing the diffraction characteristics of the diffraction grating element 20B of the example 3. In the diagram, the wavelength dependence of the diffraction efficiency when the incident angle θ (refer to FIG. 10) of the light is the Bragg incident angle at a wavelength of 1.55 μm is shown with respect to the TE polarized light and the TM polarized light, respectively. Each parameter was designed so that the polarization dependence and the wavelength dependence of the diffraction efficiency was as small as possible, and the diffraction efficiency was as large as possible at a waveband of 1.52 μm–1.57 μm. As demonstrated in the diagram, in the case of the example 3 also, the diffraction efficiency of the TE polarized light and the TM polarized light were high as 95% or more, respectively, in a wide wavelength band. The difference of the diffraction efficiency between the TE polarized light and the TM polarized light was 2% or less. As described above, in the diffraction grating element 20 in accordance with this embodiment, it is possible to improve the diffraction efficiency and to reduce the polarization dependence of the diffraction efficiency in a wide wavelength band.

Further, in the example 3, since the second medium 22 and the fifth medium 25 can be subjected to the etching simultaneously, fabrication thereof is easy. Here, as the sixth medium 26, it is preferred to use a predetermined material of which etching rate is slower than that of the second medium 22 and the fifth medium 25 for fabricating thereof. Also, it is possible to subject the second medium 22, the fifth medium 25 and the sixth medium 26 to the etching simultaneously. In such case, it is preferred that the etching rate of the fourth medium 24 is slow.

THIRD EMBODIMENT

Next, a third embodiment of a diffraction grating element in accordance with the present invention will be described. FIG. 12 is an explanatory diagram of a diffraction grating element 30 in accordance with the third embodiment. The diagram shows a section of the diffraction grating element 30 when the same is cut off at a plane perpendicular to the grating. The diffraction grating element 30 shown in the diagram comprises a first medium 31, a second medium 32, a third medium 33, a fourth medium 34, and a fifth medium 35.

In the diffraction grating element 30, a first plane P₁, a second plane P₂ and a third plane P₃, which are parallel to each other and aligned in order, are assumed. Here, the first medium 31 is provided at the outer side than the first plane P₁ (upper side in the diagram) being in contact with the first plane P₁. Between the second plane P₂ and the third plane P₃, the second medium 32 and the third medium 33 are disposed alternately in a predetermined direction parallel to the first plane P₁ being in contact with the second plane P₂ and the third plane P₃ to form a diffraction grating. The fourth medium 34 is provided at the outer side than the third plane P₃ (lower side in the diagram) being in contact with the third plane P₃. The fifth medium 35 is formed between the first plane P₁ and the second plane P₂ being in contact with the first plane P₁ and the second plane P₂.

In the diffraction grating element 30, between the fourth medium 34 and fifth medium 35, the second medium 32 and the third medium 33 are disposed alternately to form a diffraction grating. The light, which enters the diffraction grating from the first medium 31, passes through the fifth medium 35, and is diffracted at the diffraction grating portion and emitted to the fourth medium 34. Or, the light, which enters the diffraction grating from the fourth medium 34, is diffracted at the diffraction grating portion, and emitted to the first medium 31 through the fifth medium 35.

Each region in the second medium 32 and the third medium 33 has a rectangular section, respectively. In the diffraction grating portion formed with the diffraction grating, which is formed of the second medium 32 and the third medium 33 disposed alternately in a predetermined direction, it is assumed that the period of the diffraction grating is Λ; the ratio that the second medium 32 occupies in the period Λ (duty ratio) is f. It is assumed that the distance between the first plane P₁ and the second plane P₂ (i.e., thickness of the fifth medium 35) is h₅. It is assumed that the distance between the second plane P₂ and the third plane P₃ (i.e., height of the grating) is H. It is assumed that the index of refraction of the first medium 31 is n₁; the index of refraction of the second medium 32 is n₂; the index of refraction of the third medium 33 is n₃ (n₃<n₂); the index of refraction of the fourth medium 34 is n₄; and the index of refraction of the fifth medium 35 is n₅.

Here, the average index of refraction n_(av) of the diffraction grating portion between the second plane P₂ and the third plane P₃ is expressed by the above expression (1). Also, the average index of refraction n_(av) is between the index of refraction n₂ of the second medium 32 and the index of refraction n₃ of the third medium 33, and satisfies the relational expression of the above expression (2).

Same as the case of the second embodiment, the fifth medium 35 may be formed of a multi-layer film for reducing the reflection, or may be a film of single layer. In the case of a film of single layer, the index of refraction n₅ of the fifth medium 35 satisfies the above-described relational expression (5). By being arranged as described above, in the diffraction grating element 30 in accordance with this embodiment, the reflection at the boundary face is reduced and the diffraction characteristics are prevented from being degraded. Further, it is preferred that the index of refraction n₅ of the fifth medium 35 satisfies the above relational expression (7).

Further, to reduce the reflection at the boundary face in a wide waveband, it is preferred that the height h₅ of the fifth medium 35 is equal to or less than the wavelength order. For example, 5 μm or less is preferred. Particularly, given that the angle of the light with a wavelength λ in the fifth medium 35 is θ₅, it is preferred that the thickness h₅ of the fifth medium 35 satisfies the above relational expression (9). Further, when the light enters at a Bragg angle, the above expression (9) is expressed by the above expression (11). The above expression (11) is derived assuming Bragg incident angle. However, if not Bragg incident angle, the above expression is approximately applicable.

Same as the case of the first embodiment, it is preferred that the index of refraction n₄ of the fourth medium 34 satisfies the above expression (3) or expression (4). By being arranged as described above, in the diffraction grating element 30 in accordance with this embodiment, the reflection at the boundary face is reduced, and the diffraction characteristics is prevented from being degraded.

In accordance with the above expressions, the index of refraction n₁–n₃ and the thickness h₅ of each medium are determined. After that, the diffraction characteristics of the diffraction grating element 30 are analyzed by means of the RCWA. The duty ratio f, the grating period Λ and the height of the grating H are optimized by means of the optimizing technique; thereby the diffraction grating element 30 with satisfactory diffraction characteristics is designed.

The above-description has been made assuming that the fifth medium 35 is a film of uniform single layer. However, the fifth medium 35 may be formed of a multi-layered film for reducing the reflection. In the case of multi-layered film, the reflection of the TE polarized light and the TM polarized light is controlled respectively and the diffraction efficiency is improved. Further, by utilizing the polarization dependence of the multi-layered film, the polarization dependence of the diffraction efficiency can be reduced. Furthermore, it is expected that the high diffraction light and the evanescent wave be also reduced.

Same as the modified example of the second embodiment, in this embodiment also, the fifth medium 35 may be formed of a plurality of media disposed alternately in a predetermined direction. Here, the average index of refraction n₅ of the fifth medium 35 is expressed by the above expression (13). By using the average index of refraction n₅ expressed by the above expression (13), it is possible to discuss same as the above-described diffraction grating element 30.

Next, a production method of the diffraction grating element 30 in accordance with the third embodiment will be described. Same as the case of the first embodiment, the diffraction grating element 30 in accordance with the third embodiment can be fabricated by a first production method, in which etching or lift-off is used; or a second production method using a predetermined material of which index of refraction can be changed by a radiation of an energy beam. It is preferred that the fourth medium 34 is formed of a predetermined material of which etching rate is slower than that of the second medium 32 and the third medium 33, from any one of the followings; i.e., Al₂O₃, MgO, Nd₂O₃ and a fluorinated compound (AlF₃, MgF₂, CaF₂, NdF₃ and the like).

Next, an example of the diffraction grating element 30 in accordance with the third embodiment will be described. FIG. 13 is an explanatory diagram of a diffraction grating element 30A in accordance with an example 4. In the diffraction grating element 30A of the example 4, the fifth medium 35 is formed of two media 35 a and 35 b disposed alternately in a predetermined direction. The diffraction grating element 30A of the example 4, the first medium 31 was constituted of air (n₁=1), the second medium 32 was formed of Ta₂O₅ (n₂=1.98), the third medium 33 was constituted of air (n₃=1), the fourth medium 34 was formed of silica glass (n₄=1.45); in the fifth medium 35, the medium 35 a was formed of silica glass (n_(5a)=1.45), and the medium 35 b was constituted of air (n_(5b)=1). The duty ratio f and f₅ were 0.60, the grating period Λ was 1.01 μm, the height H of the grating was 1.45 μm, and the thickness h₅ of the fifth medium 35 was 0.33 μm.

FIG. 14 is a graph showing the diffraction characteristics of the diffraction grating element 30A of the example 4. In the diagram, the wavelength dependence of the diffraction efficiency when the incident angle θ (refer to FIG. 13) of the light is the Bragg incident angle at a wavelength of 1.55 μm is shown with respect to the TE polarized light and the TM polarized light, respectively. Each parameter was designed so that the polarization dependence and the wavelength dependence of the diffraction efficiency was as small as possible, and the diffraction efficiency was as large as possible at a waveband of 1.52 μm–1.57 μm. As demonstrated in the diagram, in the case of the example 4 also, the diffraction efficiency of the TE polarized light and the TM polarized light were high as 95% or more, respectively, in a wide wavelength band. The difference of the diffraction efficiency between the TE polarized light and the TM polarized light was 2% or less. As described above, in the diffraction grating element 30 in accordance with this embodiment, it is possible to improve the diffraction efficiency and to reduce the polarization dependence of the diffraction efficiency in a wide wavelength band. Further, in the example 4, since the second medium 32 and the fifth medium 35 can be subjected to the etching simultaneously, the fabrication thereof is easy.

FOURTH EMBODIMENT

A fourth embodiment of a diffraction grating element in accordance with the present invention will be described. FIG. 15 is an explanatory diagram of a diffraction grating element 40 in accordance with the fourth embodiment. The diagram shows a section of the diffraction grating element 40 when the same is cut off at a plane perpendicular to the grating. The diffraction grating element 40 shown in this diagram comprises a base plate 41, a first reflection-inhibiting portion 42, a diffraction grating portion 43, and a second reflection-inhibiting portion 44.

In the diffraction grating element 40, provided on the base plate 41 is the first reflection-inhibiting portion 42; provided on the first reflection-inhibiting portion 42 is the diffraction grating portion 43; and provided on the diffraction grating portion 43 is the second reflection-inhibiting portion 44. The second reflection-inhibiting portion 44 is in contact with the first medium 45. In the diffraction grating portion 43, the second medium 43 a and the third medium 43 b are disposed alternately in a predetermined direction substantially parallel to the base plate 41; thereby a diffraction grating is formed. In the second reflection-inhibiting portion 44, a medium 44 a is provided on the second medium 43 a; and a medium 44 b is provided on the third medium 43 b. The diffraction grating element 40 is designed so that the reflectance is 10% or less.

In the diffraction grating element 40, the light, which enters the diffraction grating from the first medium 45, passes through the second reflection-inhibiting portion 44 and diffracted at the diffraction grating portion 43, and emitted to the base plate 41 through the first reflection-inhibiting portion 42. Or, the light, which enters the diffraction grating from the base plate 41, passes through the first reflection-inhibiting portion 42 and is diffracted at the diffraction grating portion 43, and emitted to the first medium 45 through the second reflection-inhibiting portion 44.

Here, the diffraction grating portion 43 is defined as below. That is, given that the direction where the second medium 43 a and the third medium 43 b are disposed alternately is the x-direction; the direction where the first reflection-inhibiting portion 42, the diffraction grating portion 43, and the second reflection-inhibiting portion 44 are disposed in order is the z-direction. And given that the period of the diffraction grating is Λ; the ratio that the second medium 43 a makes up in the period Λ (duty ratio) is f; the length of the first reflection-inhibiting portion 42 in the z-direction (i.e., height of the first reflection-inhibiting portion 42) is h_(ar1); the length of the second reflection-inhibiting portion 44 in the z-direction (i.e., height of the second reflection-inhibiting portion 44) is h_(ar2); and the length of the diffraction grating portion 43 in the z-direction (i.e., height of the grating) is H.

And given that the average index of refraction n_(av)(z) is: $\begin{matrix} {{{n_{av}(z)} = \sqrt{\frac{\int_{0}^{\Lambda}{{n^{2}\left( {x,z} \right)}\ {\mathbb{d}x}}}{\Lambda}}},} & (15) \end{matrix}$ the modulation of the index of refraction Δn(z) is: $\begin{matrix} {{{\Delta\;{n(z)}} = \sqrt{\frac{\Lambda{\int_{0}^{\Lambda}{\left\{ {{n^{2}\left( {x,z} \right)}\  - {n_{av}^{2}(z)}} \right\}^{2}{\mathbb{d}x}}}}{\left\{ {\int_{0}^{\Lambda}{{n^{2}\left( {x,z} \right)}\ {\mathbb{d}x}}} \right\}^{2}}}},{and}} & (16) \end{matrix}$ the diffraction capacity P(z1, z2) from a position z1 to a position z2 in the z-direction is: $\begin{matrix} {{P\left( {{z1},{z2}} \right)} = {\int_{z1}^{z2}{\Delta\;{n(z)}\ {{\mathbb{d}z}.}}}} & (17) \end{matrix}$ The diffraction grating portion 43 is defined as below; i.e., the diffraction capacity thereof is larger than 50% of the entire diffraction capacity including the first reflection-inhibiting portion 42, the diffraction grating portion 43 and the second reflection-inhibiting portion 44. Also, since the degrading of the characteristics due to the diffraction in the reflection-inhibiting portion is reduced, it is preferred that the modulation of the index of refraction in the diffraction grating portion 43 is larger than the modulation of the index of refraction in the first reflection-inhibiting portion 42 and the second reflection-inhibiting portion 44. Further, since the modulation of the index of refraction in the diffraction grating portion can be easily made larger, it is preferred that the maximum refraction in the diffraction grating portion 43 is larger than the index of refraction in the base plate 41 and the first medium 45. Furthermore, when the period Λ of the diffraction grating in the diffraction grating portion 43 is equal to or less than the wavelength of the light, the reflection is not only reduced, but also diffraction of a high order does not occur. Accordingly, it is preferred that the period Λ of the diffraction grating in the diffraction grating portion 43 is 1.675 μm or less.

In the diffraction grating element 40, given that the base plate 41 is formed of silica glass (index of refraction: 1.444); the second medium 43 a of the diffraction grating portion 43 is formed of Ta₂O₅ (index of refraction: 2.107); the medium 44 a of the second reflection-inhibiting portion 44 is formed of SiO₂; and the first medium 45, the third medium 43 b and the medium 44 b are constituted of air (index of refraction: 1), f and H of the diffraction grating portion 43 are designed by means of the RCWA; and h_(ar1) and h_(ar2) of the reflection-inhibiting portions are designed by means of an analysis based on an equivalent model, which will be described below.

The analysis based on the equivalent model is a method as described below. That is, given that the first reflection-inhibiting portion 42, the diffraction grating portion 43 and the second reflection-inhibiting portion 44 is formed of a single layer film respectively, and each of them has an average index of refraction of the medium included therein; and given that the phase change of the light by the diffraction in the diffraction grating portion 43 is 90°, and replacing the diffraction grating element 40 with a multi-layer film, the diffraction efficiency of the first-order transmission and the diffraction efficiency of the zero-order reflection are analyzed. The transmittance and the reflectance of the multi-layer film are equivalent to the first-order transmission diffraction efficiency and the zero-order reflection diffraction efficiency in the diffraction grating element 40 respectively. Accordingly, by using the equivalent model, the designing theory of the multi-layer film, which is represented by an optical filter, becomes applicable; thus, the reducing design of the zero-order reflection diffraction efficiency in the diffraction grating element 40 can be made easily. Finally, a fine adjustment of the designs of f, H, h_(ar1) and h_(ar2) is preferably made on the entire diffraction grating element 40 using the RCWA, which has high accuracy in analysis.

FIG. 16 is a graph showing the characteristics of the zero-order reflection diffraction efficiency of the diffraction grating element in accordance with the fourth embodiment and the zero-order reflection diffraction efficiency of the above-described equivalent model. The graph shows the characteristics of the zero-order reflection diffraction efficiency of the diffraction grating element 40 which is actually fabricated and the above-described equivalent model under the conditions that period Λ=1.0 μm, f=0.579, H=1.164 μm, h_(ar2)=0.252 μm, h_(ar1)=−0.2 μm, the waveband of the light is 1550 nm band (C band) and the incident angle θ of the light is 50.580°. Here, h_(ar1) is a minus value. The absolute value thereof represents the thickness of the first reflection-inhibiting portion; the sign represents the structure of the reflection-inhibiting portion as described later. In FIG. 16, the characteristics indicated with the broken line represents a result of analysis of the diffraction grating element 40, which was actually fabricated; and the characteristics indicated with the solid line represents a result of analysis using the above-described equivalent model. As is demonstrated in the graph, although a minute difference is found in the central wavelength, according to the designing method using the equivalent model, precise characteristics of the diffraction grating element 40 of the embodiment can be obtained.

The diffraction grating element 40 is designed by optimizing f, H, h_(ar1) and h_(ar2) by applying the designing method in which the above-described equivalent model is used. In this design, under such conditions that the waveband of the light is 1550 nm band (C band) and the incident angle θ of the light is 50.58°, the optimization is made in a range of h_(ar1) from −0.5 μm to 0.3 μm (0.1 μm interval).

Here, when the h_(ar1) is a positive number, the following fact is indicated; i.e., that the first reflection-inhibiting portion 42 is formed of the same medium as the medium 43 a of the diffraction grating portion 43. Also, when the h_(ar1) is a minus number, the following fact is indicated; i.e., the first reflection-inhibiting portion 42 is formed of the same medium as the medium of the base plate 41. FIG. 17 is an explanatory diagram of a diffraction grating element 40A in accordance with an example 5. FIG. 18 is an explanatory diagram of a diffraction grating element 40B in accordance with an example 6. Both of FIG. 17 and FIG. 18 show a section of the diffraction grating element taken away at a plane perpendicular to the grating, respectively.

The diffraction grating element 40A is an example of the diffraction grating element 40 of the fourth embodiment when h_(ar1) is a plus number. The diffraction grating element 40B is an example of the diffraction grating element 40 of the fourth embodiment when h_(ar1) is a minus number. The diffraction grating element 40A is fabricated by carrying out an etching on the second medium 43 a, which is formed all over the surface of the base plate 41, and the etching is terminated before reaching the base plate 41. Accordingly, the same medium as the second medium 43 a forms the first reflection-inhibiting portion 42.

On the other hand, the diffraction grating element 40B is an example of the diffraction grating element 40 of the fourth embodiment when h_(ar1) is a minus number. The diffraction grating element 40B is fabricated by, for example, carrying out an etching on the second medium 43 a, which is formed all over the surface of the base plate 41, and the etching is carried out until a part of the base plate 41 is etched. Accordingly, the diffraction grating element 40B is constituted of the medium 42 a and the medium 42 b formed alternately; the medium 42 a is the same medium as that of the base plate 41, and the medium 42 b is constituted of air.

The results of the above optimization are shown in the table 1 and FIG. 19–FIG. 21.

TABLE 1 Minimum Maximum diffraction diffraction Aspect efficiency efficiency h_(ar1)(μm) f H(μm) h_(ar2)(μm) ratio (%) (%) 1 −0.500 0.580 1.119 0.241 4.43 95.4 96.6 2 −0.400 0.587 1.115 0.267 4.31 96.7 97.7 3 −0.300 0.581 1.141 0.256 4.05 97.6 98.6 4 −0.200 0.579 1.164 0.252 3.84 98.0 99.2 5 −0.100 0.649 1.293 0.423 5.17 96.7 97.4 6 0.000 0.656 1.308 0.408 4.99 96.5 97.2 7 0.100 0.576 1.213 0.412 3.84 93.1 93.7 8 0.200 0.644 1.256 0.288 4.34 90.3 91.5 9 0.300 0.590 1.238 0.316 3.79 94.9 95.6

FIG. 19 is a graph showing the diffraction efficiency of the diffraction grating element in accordance with the fourth embodiment. FIG. 19 shows the plotted minimum diffraction efficiency and the maximum diffraction efficiency, which are listed in the table 1. Here, the wording maximum diffraction efficiency and minimum diffraction efficiency means the maximum diffraction efficiency and the minimum diffraction efficiency in the C band including the TE polarized light and the TM polarized light. According to the table 1 and FIG. 19, it is demonstrated that the diffraction grating element 40 has the diffraction efficiency of 90% or more, and the polarization dependence thereof is small. In the first-third embodiments, an AR layer is formed on the diffraction grating portion which is formed of the second medium and third medium. That is, a layer for absorbing difference of the index of refraction between the medium, which is on the outside of the diffraction grating portion, and the diffraction grating portion is formed; and thereby reflected light is prevented from returning. Contrary to this, the reflection-inhibiting portion of the diffraction grating element 40 has the average index of refraction of which conditions are different from those of the AR layer in the first-third embodiments. However, the AR layer between the base plate 41 and the first medium 45 is constituted of a multi-layer film including the first reflection-inhibiting portion 42, the diffraction grating portion 43 and the second reflection-inhibiting portion 44; thereby the entire reflection in the diffraction grating element 40 is controlled.

FIG. 20 is a graph showing the aspect ratio of the grooves in the diffraction grating element in accordance with the fourth embodiment. According to FIG. 20, when h_(ar1) is −0.2 μm or 0.1 μm, since the aspect ratio is particularly small, it is understood that the diffraction grating portion 43 can be formed easily.

FIG. 21 is a graph showing the tolerance of groove depth of the diffraction grating element in accordance with the fourth embodiment. Here, the wording “tolerance of groove depth” means a tolerance of changes of h_(ar1) when the changes of the diffraction efficiency allowed by 1%; i.e., an error of groove depth. According to FIG. 21, when h_(ar1) is approximately −0.2 μm, tolerance of the error of groove depth is large. Accordingly, it is understood that the diffraction grating element 40 can be fabricated easily.

MODIFIED EXAMPLE

The present invention is not limited to the above-described embodiments, but a variety of modifications are conceivable. For example, in each of the above embodiments, the configuration of the section of each region in the second medium and the third medium, which constitute the diffraction grating portion, is a rectangle. However the configuration is not always required to be rectangle, but, for example, the configuration may be a trapezoid. In the above-described examples, the duty ratio f, f₅ and f₆ are equal to each other. They may be different from each other. If so, the diffraction characteristics can be further increased. Further, in the diffraction grating element of each embodiment, the light may enter from the first medium side, or the light may enter from the fourth medium side.

Furthermore, in the above-described embodiments, the second medium and the third medium are disposed alternately being in contact with each other to form the diffraction grating portion. However, a different medium may be provided between the second medium and the third medium. Such example of modification mode will be described taking the diffraction grating element 30A in accordance with the example of the third embodiment as an example. FIG. 22 is an explanatory diagram of a diffraction grating element 30B in accordance with a mode of modification. FIG. 22 shows a section of the diffraction grating element, which is cut off at a plane perpendicular to the grating. The diffraction grating element 30B shown in FIG. 22 has the same constitution as that of the diffraction grating element 30A; but between the second medium 32 and the third medium 33, a medium 36 is formed. For example, in the case where the medium 35 a is formed of SiO₂, and when a process for adhering SiO₂ while etching the second medium 32 is introduced in order to supplement defects on side walls of the medium 35 a due to the etching, a diffraction grating element 30B in which the medium 36 is formed of SiO₂ is fabricated. Also, in the case where the medium 32 is formed of Ta₂O₅, and when a process for adhering Ta₂O₅ while etching the second medium 32 is introduced in order to supplement defects on side walls of the medium 32 due to the etching, a diffraction grating element 30B in which the medium 36 is formed of Ta₂O₅ is fabricated.

Each example is designed based on the waveband of 1.5 μm–1.6 μm, but is not limited thereto. In the designing of the diffraction grating, the law of similitude is applicable. Accordingly, for example, when altering the central wavelength from 1.55 μm to 1.3 μm, the alteration is achieved only by multiplying every designing parameter (period and thickness) having a unit of length by 1.3/1.55. As described above, the diffraction grating having a central wavelength within a waveband of 1.26 μm14 1.675 μm, which is used in the optical communication, can be designed easily. 

1. A diffraction grating element, comprising: given first-fourth planes disposed parallel with each other in order, a first medium having an index of refraction n₁ provided at the outer side than the first plane being in contact with the first plane, a second medium having an index of refraction n₂ and a third medium having an index of refraction n₃, n₃<n₂ disposed alternately in a predetermined direction parallel with the first plane between the second plane and the third plane being in contact with the second plane and the third plane to constitute a diffraction grating, a fourth medium having an index of refraction n₄ provided at the outer side than the fourth plane being in contact with the fourth plane, a fifth medium having an average index of refraction n₅ provided between the first plane and the second plane being in contact with the first plane and the second plane, and a sixth medium having an average index of refraction n₆ provided between the third plane and the fourth plane being in contact with the third plane and the fourth plane, wherein given that an average index of refraction between the second plane and the third plane is n_(av), the average index of refraction n₅ of the fifth medium satisfies a relational expression of “n₁<n₅<n_(av)” or “n_(av)<n₅<n₁”, and the average index of refraction n₆ of the sixth medium satisfies a relational expression of “n₄<n₆<n_(av)” or “n_(av)<n₆<n₄”.
 2. The diffraction grating element according to claim 1, wherein the average index of refraction n₅ of the fifth medium satisfies a relational expression of “(n₁n_(av))^(1/2)−0.2<n₅<(n₁n_(av))^(1/2)+0.2”.
 3. The diffraction grating element according to claim 2, wherein the average index of refraction n₆ of the sixth medium satisfies a relational expression of “(n₄n_(av))^(1/2)−0.2<n₆<(n₄n_(av))^(1/2)+0.2”.
 4. The diffraction grating element according to claim 1, wherein, given that the period of the diffraction grating is Λ; the thickness of the fifth medium with respect to a direction perpendicular to the first plane is h₅; and light of a wavelength λ enters the diffraction grating, a wavelength λ of light that satisfies a relational expression of “λΛ/4(4n₅ ²Λ²−λ²)^(1/2)<h₅<3λΛ/4(4n₅ ²Λ²−λ²)^(1/2)” is present in a waveband of 1.26 μm–1.675 μm.
 5. The diffraction grating element according to claim 3, wherein, given that the period of the diffraction grating is Λ; the thickness of the sixth medium with respect to a direction perpendicular to the first plane is h₆; and light of a wavelength λ enters the diffraction grating, the wavelength λ of light that satisfies a relational expression of “λΛ/4(4n₆ ²Λ²−λ²)^(1/2)<h₆<3λΛ/4(4n₆ ²Λ²−λ²)^(1/2)” is present in a waveband of 1.26 μm–1.675 μm.
 6. The diffraction grating element according to claim 1, wherein the fifth medium includes a plurality of media disposed alternately in the predetermined direction.
 7. The diffraction grating element according to claim 6, wherein the sixth medium is made of a plurality of media disposed alternately in the predetermined direction.
 8. The diffraction grating element according to claim 1, wherein a wavelength of light in which each diffraction efficiency of TE polarized light and TM polarized light is 90% or more, is present.
 9. The diffraction grating element according to claim 1, wherein a wavelength of light in which the difference of the diffraction efficiency between TE polarized light and TM polarized light is 5% or less is present.
 10. The diffraction grating element according to claim 1, wherein the difference between the index of refraction n₂ of the second medium and the index of refraction n₃ of the third medium is 0.7 or more.
 11. The diffraction grating element according to claim 10, wherein the second medium is any one of TiO₂, Ta₂O₅ and Nb₂O₅, and the third medium is a gas.
 12. The diffraction grating element according to claim 1, wherein the second medium or the third medium is made of a predetermined material of which index of refraction changes by an irradiation of energy beam.
 13. The diffraction grating element according to claim 12, wherein the predetermined material is a diamond-like carbon.
 14. The diffraction grating element according to claim 1, wherein the first medium, the fourth medium, the fifth medium or the sixth medium is made of a predetermined material of which etching rate is slower than that of the second medium or the third medium.
 15. The diffraction grating element according to claim 14, wherein the predetermined material is any one of Al₂O₃, MgO, Nd₂O₃ and a fluorinated compound.
 16. The diffraction grating element according to claim 14, wherein the second medium or the third medium is any one of TiO₂, Nb₂O₅, Ta₂O₅, SiN, SiO₂, SiO, ZrO₂ and Sb₂O₃.
 17. The diffraction grating element according to claim 1, wherein the second medium and the third medium are in contact with each other. 